|Publication number||US7466627 B2|
|Application number||US 11/254,653|
|Publication date||Dec 16, 2008|
|Filing date||Oct 20, 2005|
|Priority date||Oct 20, 2005|
|Also published as||US20070091722|
|Publication number||11254653, 254653, US 7466627 B2, US 7466627B2, US-B2-7466627, US7466627 B2, US7466627B2|
|Original Assignee||Pgs Geophysical As|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (15), Referenced by (5), Classifications (10), Legal Events (3)|
|External Links: USPTO, USPTO Assignment, Espacenet|
1. Field of the Invention
The invention relates generally to the field of marine seismic surveying. More specifically, the invention relates to methods and systems for transferring seismic data from a fixed-position data recorder or telemetry unit to a seismic vessel or other moving data collection device.
2. Background Art
Marine seismic data acquisition systems known in the art include recording buoys which are anchored to the sea bed. A typical recording buoy includes data storage equipment known in the art for storing seismic data. Such data storage equipment may include storage devices such as tape drives, magnetic hard drives, solid state random access memory and the like. The seismic data are acquired from various seismic sensors. In seismic data acquisition systems that use recording buoys, the seismic sensors are typically disposed in one or more cables positioned on the water bottom, such a cable being known as an “ocean bottom cable”. The sensors in the cable generate electrical and/or optical signals corresponding to the particular parameter being measured, the parameter being pressure, time gradient of pressure and/or a particle motion related parameter such as velocity or acceleration. Electrical and/or optical conductors in the cable transfer the signals generated by the seismic sensors to the data storage equipment in the recording buoy.
The data storage equipment on the recording buoy may be interrogated by a seismic data processing and recording system disposed on a seismic vessel or elsewhere. The interrogation may be performed by connecting a data transfer cable between the seismic data processing and recording system on the seismic vessel and the storage equipment in the recording buoy, or, preferably, the interrogation may be performed by wireless telemetry.
In a typical seismic survey using ocean bottom cables and recording buoys, a plurality of ocean bottom cables are deployed along the water bottom in a selected pattern, and the seismic vessel moves along the water surface in a predetermined pattern near the positions of the ocean bottom cables. The seismic vessel, or another vessel, tows one or more seismic energy sources. The seismic energy sources are actuated at selected times, and the signals generated by the sensors in the ocean bottom cables in response to detecting seismic energy are transferred to the storage equipment in the recording buoy. In survey techniques known in the art, the data stored in the recording buoys are accessed by interrogating the data storage equipment after completing the acquisition, or between parts of the acquisition. In any event, to establish wireless telemetry, the seismic vessel is moved to a location where wireless communication can be established between the recording buoy and the seismic vessel, and the vessel remains substantially at that location during the storage device interrogation.
It is desirable to be able to transfer seismic data from the recording buoy to the seismic vessel while the seismic vessel is moving during a survey using ocean bottom cables. The ability to transfer data while the seismic vessel is moving would enable, among other things, more rapid quality evaluation of the seismic data. Quality control of the data during acquisition could provide, for example, that the seismic vessel is able to return immediately to any portion of the predetermined pattern to reacquire the seismic data in the event any of the data in such portion are substandard. Such ability may provide cost savings by reducing the operating time for the seismic vessel.
Wireless telemetry devices known in the art for transferring data between two substantially fixed position devices are disclosed, for example, in U.S. Pat. No. 4,663,744 issued to Russell et al. The Russell et al. '744 patent discloses a real time seismic telemetry system including a central command station for communication with a plurality of remote data acquisition units, such as recording buoys. The central command station has a command unit for controlling the operation of a transmitter, for providing instructions to the data acquisition units. The data acquisition units receive the instructions on a receiver and process the instructions in a logic control circuit. Seismic data are detected by one or more sensors and converted to digital data for transmission through a transmitter which is tuned to a discrete channel for each data acquisition unit. The command station has a PCM receiver tuned to each of the channels for demodulating the data stream therefrom. A digital receiver is provided in the command unit for synchronizing and processing the data. The digital receiver synchronizes both to the bit rate and to the beginning and ending of the digital word such that data contained in the digital word can be multiplexed onto a data bus. The data bus is controlled by an external storage/control for storage of the data from all of the digital receivers for all of the discrete channels.
Direct adaptation of such wireless seismic telemetry systems known in the art to transfer of seismic data (or between two moving vessels) has proven difficult because seismic telemetry systems known in the art for transmitting data between fixed locations typically use directionally sensitive antennas. Directionally sensitive antennas have a large magnetic dipole moment along essentially one direction and provide relatively high signal gain along that direction, but provide substantially no signal sensitivity along any other direction. Thus, it is impracticable to use fixed position, directionally sensitive antennas to communicate signals between two devices that move relative to each other. Omni directional antennas provide substantially uniform signal gain in any direction from the antenna, but the gain is relatively small, and for high data-rate telemetry, such as would be used in multi-channel seismic data acquisition, low signal gain would require relatively high telemetry transmitter power. Because typical recording buoys are powered by batteries, it is desirable to keep the power consumption of the telemetry system as small as practical. Therefore, the power output of the telemetry transmitter in a typical recording buoy would be limited. Accordingly, there is a need for a seismic data telemetry system that enables signal communication between a recording buoy and a moving seismic vessel that does not require a high power transmitter.
One aspect of the invention is a seismic data acquisition system. A seismic data telemetry system according to this aspect of the invention includes a seismic vessel. The system includes a seismic data gathering unit in operative connection with at least one seismic sensor. The system includes a first antenna disposed on the seismic vessel and a second antenna disposed on the data gathering unit, At least one of the antennas is directionally sensitive. Means are included for orienting a sensitive direction of the directionally sensitive antenna toward the other antenna.
Another aspect of the invention is a method for maintaining telemetry between a seismic data gathering unit and a seismic vessel. A method according to this aspect of the invention includes sensing a direction between the seismic vessel and the data gathering unit, and orienting a directionally sensitive antenna substantially along the direction.
Another aspect of the invention is a method for conducting a marine seismic data acquisition survey. A method according to this aspect of the invention includes deploying at least one ocean bottom cable on a bottom of a body of water. The ocean bottom cable has a plurality of seismic sensors thereon at spaced apart locations. A seismic energy source is towed from a seismic vessel near the surface of the body of water, and the source is actuated at selected times. Seismic signals are detected at the sensors, and the detected signals are communicated to a data gathering unit. A direction between the seismic vessel and the data gathering unit is determined. A directionally sensitive antenna is oriented substantially along the direction, and the communicated signals are telemetered from the gathering unit to the seismic vessel through the antenna.
Other aspects and advantages of the invention will be apparent from the following description and the appended claims.
A seismic data acquisition system that can be used with various embodiments of a telemetry system according to the invention is shown schematically in plan view in
In the present embodiment, the seismic sensors 18 can be disposed along cables 16 placed on the water bottom in a selected pattern. The sensors 18 are typically hydrophones and geophones, included in a typical configuration in a cable known in the art as an “ocean bottom cable” although the type of sensor and the type of cable are not limitations on the scope of the invention. The sensors 18, generate electrical and/or optical signals that correspond to the parameters being measured. The measured parameters are typically pressure or time gradient of pressure, and a particle motion-related parameter such as velocity or acceleration. The ocean bottom cables 16 may include electrical and/or optical conductors (not shown separately) therein for communicating the electrical and/or optical signals to a data gathering unit such as a recording buoy 20. The conductors may also carry electrical power to various signal amplification and processing circuits (not shown in the Figures) such as preamplifiers and digitizers, located along the cables 16.
The recording buoy 20 can include signal conditioning and recording equipment (not shown separately in
In the present embodiment, the recording buoy 20 and the recording system 12 may each include a directional antenna module, 22A and 22B, respectively. The directional antenna modules 22A, 22B each include a directionally sensitive antenna 30 (see
In a first embodiment of the invention, as the seismic vessel 10 moves along the water 11 surface, orientation of the sensitive direction of the antenna 30 in each directional antenna module 22A, 22B is maintained toward the corresponding antenna in the other one of the modules 22A, 22B to maintain telemetry signal communication. Generally, an antenna module according to the invention automatically controls the orientation of the sensitive direction of each antenna toward the corresponding telemetry antenna. Various embodiments of apparatus to control the orientation of the sensitive direction will be further explained below with reference to
One embodiment of a directionally sensitive (“directional”) antenna module and its antenna orientation control system, suitable for use as module 22A or 22B, is shown in
Referring once again to
In the present embodiment, control of the orientation of the sensitive direction of the seismic data telemetry antenna of a selected one of the modules 22A or 22B (located on either the seismic vessel of the recording buoy) can be performed by determining the geodetic direction of the seismic data telemetry antenna of the corresponding module with respect to the selected module, and rotating the reflector 32 and amplifier/waveguide 34 of the selected module until a measured geodetic orientation of the sensitive direction of the reflector 32 matches the determined geodetic direction of the corresponding antenna. In the present embodiment, the geodetic direction of the corresponding antenna may be determined as follows. With reference to
An omnidirectional antenna 46 may receive similarly determined geodetic position information (contained in low frequency telemetry signals) transmitted from a low-frequency telemetry transmitter (not shown separately in
Correspondingly, the geodetic position of the selected module (22A or 22B) as measured by the GPS receiver 42 may also be communicated to the low frequency transceiver 44 for transmission to the corresponding low frequency antenna (not shown) disposed near the corresponding seismic data telemetry (high frequency) antenna.
In the present embodiment, the corresponding low frequency telemetry antenna (not shown) can be disposed nearby a corresponding GPS receiver and low frequency telemetry transceiver (not shown). The corresponding GPS receiver and low frequency telemetry transceiver send the geodetic position information for the corresponding antenna to the directional antenna module (22A or 22B), which information is detected as explained above using omnidirectional antenna 46 and low frequency transceiver 44. The received geodetic position information from the corresponding antenna, as explained above, is communicated to the controller 40. The controller 40 uses the geodetic position information for the directional antenna module and for the corresponding seismic data telemetry antenna to compute a geodetic direction from the selected directional antenna module to the corresponding seismic data telemetry antenna.
The geodetic orientation of the reflector 32 may be measured using a directional sensor 37, such as a two-channel flux-gate magnetometer or the like, affixed to the reflector 32 or the rotatable mount 39. The orientation measured by the directional sensor 37 is also communicated to the controller 40. The controller 40 operates the motor 38 until the measured orientation matches the computed geodetic direction to the corresponding antenna (not shown). Alternatively, the geodetic orientation of the reflector 32 may be determined by using devices such as a rotary position encoder coupled to the support shaft 41, such that a relative rotary orientation of the reflector 32 with respect to the module (22A or 22B) may be determined, such as by the controller 40. The geodetic orientation of the module (22A or 22B may be determined by a separate sensor, for example a two-channel magnetometer, or may be determined by using navigation data from the navigation devices in the recording system (12 in
The geodetic position information telemetry is referred to herein as “low frequency” because it is contemplated that there will be only one data channel therein (the corresponding antenna position) and the data sample rate for the one data channel will be relatively low, such as a few Hz to 100 Hz. Accordingly, the operating frequency for the telemetry transceiver 44 may be on the order of a few KHz to 1 MHz. At such low frequencies, omnidirectional antennas are generally effective at maintaining signal communication, even at relatively low transmitter power output. It is to be understood that the telemetry frequency used for communicating geodetic position information is not a limitation on the scope of the invention. As a practical matter, the frequency for such telemetry is preferably selected such that omnidirectional antennas may be used.
During operation of the telemetry system, as the seismic vessel moves with respect to the recording buoy, the measurements of geodetic position of each of the vessel and the buoy are periodically redetermined. The geodetic direction between the vessel and the buoy is correspondingly redetermined, and the antenna orientation on both the vessel and the buoy is periodically adjusted to correspond to the redetermined geodetic direction.
An alternative embodiment to the one shown in
By suitable selection of phase shift between the signals at each dipole antenna 34A, the sensitive direction of the combined antennas 34A may be electronically controlled or rotated, correspondingly to mechanically rotating the directionally sensitive reflector/amplifier/waveguide combination shown in
In the present embodiment the effective sensitive direction of the combined antennas 34A is adjusted by the controller 40 calculating a value of phase shift for each antenna 34A and communicating the respective values of phase shift to the phase shifter 35, such that constructive interference and destructive interference between the signals radiated by each antenna 34A result in high signal gain (by constrictive interference) along a selected geodetic orientation. The selected geodetic direction is toward the corresponding data telemetry antenna, just as for the embodiment of
Operation of the embodiment shown in
An alternative implementation of a directional antenna telemetry module that does not require determining of the geodetic positions of the modules on either the recording buoy or the seismic vessel is shown in
In the embodiment of
The embodiment shown in
By using at least one controllable orientation, directional antenna module in a seismic data acquisition system, it can become more practical to transfer seismic data in real time from data storage equipment on a recording buoy to data recording equipment on a seismic vessel. By transferring the data in real time from the buoy to the seismic vessel during acquisition, it then becomes possible to quality check the seismic data during the acquisition procedure itself. Performing data quality control during a survey may reduce the chance of completing the survey only to find substandard data from one or more seismic sensors. Thus, corrective action may be taken with shorter delay or less lost time. The use of directional antennas may also reduce interference between signals from a plurality of different recording buoys.
As explained above, a directional antenna module such as explained above with reference to
While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US3181146 *||Oct 23, 1961||Apr 27, 1965||Rayflex Exploration Company||Position determining system|
|US3325778 *||Aug 13, 1965||Jun 13, 1967||Sanders Associates Inc||Seismic sonobuoy|
|US3604004 *||Feb 10, 1969||Sep 7, 1971||Edward M Buyer||Dual frequency radio apparatus for data transmission and direction finding|
|US4309763 *||May 8, 1978||Jan 5, 1982||Refraction Technology, Inc.||Digital sonobuoy|
|US4663744||Aug 31, 1983||May 5, 1987||Terra Marine Engineering, Inc.||Real time seismic telemetry system|
|US4958328 *||Jul 24, 1989||Sep 18, 1990||Texaco Inc.||Marine walkaway vertical seismic profiling|
|US5303240 *||Jul 8, 1991||Apr 12, 1994||Motorola, Inc.||Telecommunications system using directional antennas|
|US5625885 *||Jul 18, 1994||Apr 29, 1997||Fujitsu Limited||Mobile communication system having pagers for providing two-way data communication between a base station and mobile stations|
|US5818385 *||Aug 12, 1996||Oct 6, 1998||Bartholomew; Darin E.||Antenna system and method|
|US5835059 *||Sep 1, 1995||Nov 10, 1998||Lockheed Martin Corporation||Data link and method|
|US5910789 *||Dec 20, 1995||Jun 8, 1999||Geco A.S.||Method for integrity monitoring in position determination|
|US5995040 *||Nov 12, 1996||Nov 30, 1999||Centre National D'etudes Spatiales||Global space radiopositioning and radionavigation system, beacon and receiver used in this system|
|US6512481 *||Oct 10, 1996||Jan 28, 2003||Teratech Corporation||Communication system using geographic position data|
|US20040217908||May 1, 2003||Nov 4, 2004||Robert Zigler||Adjustable reflector system for fixed dipole antenna|
|EP0518146A2||May 30, 1992||Dec 16, 1992||Trimble Navigation Limited||Global positioning system based method for high-accuracy and high-confidence level absolute and relative position and velocity determinations|
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US9372280||Jan 25, 2012||Jun 21, 2016||Pgs Geophysical As||System and method for in-sea electrode conditioning|
|US9377545||Feb 21, 2014||Jun 28, 2016||Pgs Geophysical As||Streamer design for geophysical prospecting|
|US9383468||Oct 2, 2013||Jul 5, 2016||Pgs Geophysical As||Streamers without tailbuoys|
|WO2009131619A2 *||Apr 1, 2009||Oct 29, 2009||Pgs Geophysical As||Method for acquiring marine ocean bottom seismic data using multiple seismic sourves|
|WO2009131619A3 *||Apr 1, 2009||Dec 30, 2009||Pgs Geophysical As||Method for acquiring marine ocean bottom seismic data using multiple seismic sourves|
|U.S. Classification||367/77, 367/15, 367/19|
|Cooperative Classification||H01Q3/06, H01Q3/36, G01V1/223|
|European Classification||G01V1/22B, H01Q3/06, H01Q3/36|
|Jul 31, 2006||AS||Assignment|
Owner name: PGS GEOPHYSICAL AS, NORWAY
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:KARLSEN, KENNETH;REEL/FRAME:018034/0805
Effective date: 20051104
|May 25, 2012||FPAY||Fee payment|
Year of fee payment: 4
|Jun 16, 2016||FPAY||Fee payment|
Year of fee payment: 8